BR0209526B1 - offshore platform for drilling for or production of hydrocarbons. - Google Patents

Description

Report of the Invention Patent for "PLATFORM MA SITUATED WIDE FOR DRILLING FOR HYDROCARBON PRODUCTION".

The present invention relates to an offshore drilling or production drilling platform consisting of a semi-submersible platform supporting a drilling and / or production rig on its upper surface.

The drilling or production of hydrocarbons (oil and gas) using floating units is currently dominated by two different types of units, ie semi-submersible vessel or platforms.

Ship-based units are recognized for their large deadweight measurement relative to production or drilling equipment and their large storage capacity for oil, fuel, etc. Disadvantages with units of this type are the dependence on the direction of environmental forces such as wind, current and waves. When environmental forces act on a vessel, the forces and movement of the vessel usually become large. To reduce the forces and movement of a moored vessel, a tower (rotational body) is generally used to steer the vessel. For production on vessels, this leads to high costs and complicates the transfer on elevators moving from the seabed (due to the requirements for the transfer of swivel brackets, etc.).

Units based on semi-submersible platforms are recognized for small movements and independence from the direction of environmental forces. Units can simply be anchored using a fixed anchor system and elevators can be connected directly to the platform receiving system. The disadvantages with a known solution of this type is the small measure of deadweight on the deck and the low storage capacity for oil, fuel, etc.

Other units that have recently been introduced for floating production are the so-called "mast buoys". These units consist of a cylindrical hull with flotation at the top and bottom at the bottom. Height (and depth) is considerably larger than the largest diameter of the units. A similar concept with a large submerged cylinder construction and a small diameter on the water surface has also been suggested. Both of these solutions and also the management of a conical submerged part are recognized by the fact that stability is achieved with the center of gravity being lower than the center of flow (as for a submerged bottle). Simplified shell-based units, such as a square or octagon submerged housing construction, have also been suggested as possible solutions.

Reduced movements are of great importance both for units that are used for drilling and for units that are used for production. When drilling, there are small tolerances for rocking and pitching movements. Typical marginal values for operations are in the region of 2 to 4 degrees. For production units, process equipment is motion sensitive. The efficiency of the equipment that is used today is reduced with swing or pitch angles above 2 to 4 degrees. Therefore, it is very important to achieve a reduction in rocking and pitching movements especially in order to achieve an efficient drilling unit in search of oil and gas production.

Thus, the main object of the present invention is to provide a offshore platform which is constructed with the prospect of achieving reduced swinging and pitching motion and also reduced swinging motion.

Another object of the invention is to provide such a platform that will combine the positive characteristics by means of boat-based units and units based on semi-submersible platforms.

An additional object of the present invention is to provide a platform which has a simple and low cost construction, since the platform can be built on a standard equipped shipyard and can in principle be built as a ship. For the purposes mentioned above, a platform of the type provided above is provided, which according to the invention is characterized in that the platform body is designed as a mainly flat-bottom cylindrical cylinder which is provided with at least one peripheral circular cutout in the bottom of the cylinder, as the center of the submerged platform's floating position is positioned lower than the center of gravity of the platform.

With this design of the cylindrical platform, with at least one cutout along the circumference or a properly fitting groove generally having upper and lower sidewalls, a considerable reduction in pitching and swaying will be achieved. These favorable results are achieved as a result of the physical conditions that will be described in more detail below.

The behavior of the platform with respect to rocking or pitching movements is related to the same forces as those that check rocking movements for a ship. When a wave is rolling towards the side of a vessel, the wave expansion and pressure downwardly on the wave will give an upward vertical force where the wave increases and thus a reduced depression force where the wave is below middle level. These forces give the ship a rocking motion. Consequently, they will impart a rocking motion (or panting motion) on the presented cylindrical platform.

In addition to variations in water pressure under the action of a probe, there are also particle movements. The water particles move in an elliptical motion that gives both accelerations and velocities that vary over a wave period. The indentation and annular section of the cylindrical body below the indentation will disturb the particle flow in the probe. The edges above and below the cutout will create large swirls in running water. The energy that is needed to create whirlwinds represents forces acting on the building. A similar effect arises at the content edge between the lower body of the cylinder and its vertical side. In addition, the annular body below the cutout gives some resistance to flow. The forces collected from the creation of the whirlwind and the resistance to flow will give forces that have a vertical component acting in the opposite direction to the buoyancy forces from the expansion of the round. Tests have shown that by properly designing the cutouts and annular body, the forces that give the swing or pitch movement will be greatly reduced.

In addition to the favorable effect mentioned above, this platform design will bring many other advantages.

Thus, a cylindrical platform will have a large deadweight measurement with respect to production or drilling equipment and large storage capacity for oil, fuel, etc. The platform will be independent of the direction of environmental forces and may be anchored with a simple fixed anchor system.

Additionally, the elevators can be directly connected to a platform receiving system without the need for swivel bracket transfer or the like.

The platform may be constructed in a normally equipped shipyard and may in principle be constructed as a ship. In addition, it will be possible to efficiently isolate the different main units in the platform from each other. The lower section of the platform will consist mainly of oil, ballast, fuel, possible drilling fluid, etc. tanks. On the upper deck of the platform there will be necessary facilities such as accommodation, machinery and power supply, process equipment and possibly drilling equipment to be arranged in separate areas. The circular (polygonal) shape of the cylinder body will give short distances between the different types of equipment. This will reduce the length and extent of cable and tube systems and will contribute to providing a cost effective platform.

The platform design allows construction to a high degree of safety against accidents such as collisions or explosions. The platform will be constructed with double sidewalls and double bottom (ballast tanks), as in a ship. This will give a high degree of safety in any accident and reduce the danger of serious consequences.

The present invention will be described in more detail below in connection with drawing examples with reference to the drawings, in which:

Figure 1 shows a partially sectioned side section of a first drawing of a platform according to the invention;

Figure 2 shows an outline of the platform of Figure 1,

Figures 3 and 4 show a cross section of a cylindrical and polygonal platform body, respectively, where the body is supplied with a central vertical axis,

Figure 5 shows a cross section of a circular cylindrical platen body without a central axis,

Figure 6 is a partially sectioned side view of a platform drawing that is without a central vertical axis;

Figures 7 and 8 show a side view similar to Figure 1 of the alternatively designed platforms of the clipping and

Figure 9 shows a side view similar to Figure 1, where the platform is supplied with a drill tower.

In the different drawings, parts and elements thereof are marked with the same reference numerals.

Figures 1 and 2 show a platform 1 consisting of a semi-submersible platform body or hull 2 which is designed as a vertical cylinder with a flat bottom 3. The platform is floating in the water 4. Lower half of the cylinder is provided with a slot peripheral or cutout 5 that runs along the entire circumference of the cylinder. In the drawing shown, the cutout 5 is, at its upper edge, generally limited by a horizontal side wall 6, while at its lower edge it is limited by an annular body 7 which is projected with perspective achieve an extra cushioning effect on platform movement.

As shown in enlarged detail A in Figure 1, the annular body 7 has an outwardly converging upper side and lower side which may be formed by annular plates 8 and 9 which are attached to the lower end of the cylinder body 2. At the edge external to the plates 8, 9 is generally attached to a vertical annular perforated plate 10 with numerous holes 11. The plates 8, 9 form water deflection plates that run along the body side of the cylinder 2, so that the water flow changes direction and is forced through the drilling plate 10. This causes additional damping of the movement of the platform.

The damping arrangement shown may be varied in a number of ways, for example with respect to plate width 10 and distance from the cylinder body 2. This distance is dependent on the width and inclination of plates 8 and 9. Plates 8, 9 may possibly be curved as concave deflection plates or may be combined or replaced by a horizontal plate.

A similar damping arrangement may possibly be arranged with the upper edge of the cutout 5.

In the drawing of Figure 1, annular body 7 has an outer diameter which is generally similar to the diameter of the cylindrical portion 12 of the cylinder body 2 above the cutout. Additionally, only one clipping is available. However, there may be more than one cutout and thus possibly with different diameters of the limited annular section of the cylinder body cutout, ie as shown in Figure 8.

In the drawing shown, the platform body 2 has a circular cylindrical cross-section as can be seen from Fig. 2. The cylinder may in any case have a polygonal cross-section as shown in Figure 4.

The diameter D of the platform body will normally be greater than its depth T. Additionally, the float center for the submerged platform will be less than the center of gravity of the platform as for a ship.

The platform is considered to be constructed of steel, preferably with the structure of resistance elements, as for a ship. Other materials similar to concrete can also be used.

The platform features an upper deck 13 which supports different deck installations that are required for a type of gift platform. As an example, it is depicted in the drawing showing a housing 14 with a top "H" helicopter deck, an engine room 15, a workshop / warehouse 16, a drilling rig 17, a process / storage area 18, two cranes19 and a light tower 20.

As shown in Figure 1, the platform body 2 is covered with a double bottom and double side walls to reduce the extent of damage in a possible collision or explosion on the platform. Space that is limited by Double bottom and double sidewalls are divided into numerous ballast tanks 21 (bottom) and 22 (sidewalls).

In the center of the cylinder body 2, a so-called vertical or moonpool shaft 23 is arranged to receive lifting columns or other equipment that is used in drilling or oil production.

Additionally, numerous tanks 24 are arranged on the platform body in a similar manner as for a ship. These tanks can be used for oil storage, ballast or fuel storage or possibly drilling fluid that is used in drilling.

In the drawing in Figure 1, platform 1 is anchored using numerous anchor lines 25. Alternatively, the platform can be held in position using dynamic positioning as it is supplied with an active thrust system (not shown) for finality.

Figures 3-5 show examples of possible tank arrangements. Inside the ballast tanks 22 on the double-side walls, the platform body 2 is shown to be sectioned into two annular tank sections, which are divided into numerous tanks 24. In the drawing in Figures 3 and 4, the The cylinder or platform body consists of the center shaft 23 and is surrounded by an annular housing 26 for access and for the installation of pipes, pumps, etc. The drawing of Figure 5 is without a central axis and the central part of the cylinder body is here divided into four compartments or tanks 27.

Figures 6-8 show different drawings of the platform damping arrangement.

In the drawing of Figure 6, a cylindrical body 2 is provided with a peripheral cutout 30 which is limited at its upper and lower edges generally by the upper and lower horizontal sidewalls 31 and 32. Annular body 33 under cutout 30 has, in this case, the same diameter as the cylindrical portion 12 of the platform body 2 above the cutout.

The drawing in Figure 7 is similar to the drawing in Figure 6 except that the annular body 34 below the cutout 30 has a larger diameter than the cylindrical section 12 above the cutout.

Figure 8 shows a drawing where the platform body 2 is provided with two peripheral cutouts 35 and 36 with an intermediate mid-section 37. Both cutouts 35, 36 are shown to be limited primarily by the upper and lower horizontal sidewalls. The annular body 38 below the cutout 36 has in this case the same diameter as the cylindrical portion 12 of the platform body 2 above the cutouts, while section 37 is shown to have a larger diameter. The annular body 38 may, however, have the same diameter as section 37, or possibly have a larger diameter than this section.

As can be seen from Figures 6-8, the platform design according to these figures is not supplied with a verticalcentral axis.

Figure 9 shows a platform drawing corresponding to the drawing of Figure 6 with respect to the damping arrangement, but where the platform is supplied with a central vertical axis 23 and where the drill bit 39 is arranged on the platform deck above the axis.

Claims (10)

1. Offshore drilling platform for drilling for or production of hydrocarbons comprising a semi-submersible platform body (2) supporting the drilling rig and / or producing its upper surface, the platform body (2) being formed as an essentially flat-bottomed vertical cylinder, characterized in that the platform body (2) at the bottom of the cylinder is provided with at least one peripherally surrounding recess (5; 30; 35; 36) which is delimited by an annular body (7; 33; 34; 38) below the recess and diameter of the platform body is substantially larger than its draft, and the floating center of the submerged part of the platform (1) is located below the center of gravity of the platform. Platform according to Claim 1, characterized in that the platform body (2) has a circular cross-section. Platform according to Claim 1, characterized in that the platform body (2) has a polygonal cross-section. Platform according to one of Claims 1 to 3, characterized in that the annular body (7) has upper and lower sides formed by outwardly converging surfaces (8, 9), an essentially vertical annular perforated plate ( 10) being attached to the outer rim annular body (7). Platform according to one of Claims 1 to 3, characterized in that the recess (30) or recesses (35, 36) at their upper and lower edges are delimited by upper and lower horizontal side walls (31, 32). ). Platform according to claim 5, characterized in that the cylindrical portion (34) below the undercut (30) has a diameter that is larger than the diameter of the platform body (2) above the undercut. Platform according to claim 5, characterized in that the platform body (2) is provided with a plurality of circumferential recesses (35, 36), wherein the annular portions (37, 38) delimiting the recesses have different diameters. Platform according to one of the preceding claims, characterized in that the platform body (2) is provided with a central eixovertical (23) for receiving elevators or other drilling or production equipment. Platform according to one of the preceding claims, characterized in that the platform body (2) includes numerous tank sections comprising tanks (24) for storing oil, ballast or other liquids. Platform according to one of the preceding claims, characterized in that the platform body (2) is provided with a double bottom and double side walls, the space defined by the double bottom and the double side walls being divided. in numerous ballast tanks (21, 22).